Network folder synchronization

ABSTRACT

Synchronization of folders shared among multiple clients over a network is provided. A first user of a first client instantiates a folder to be shared, and the folder and its contents are synchronized with a host system. As the user makes changes to the folder and its contents on the first client, those changes are propagated to the synchronized version on the host server. Other clients who will be sharing the synchronized folder register with the host system and obtain a current version of the synchronized folder and contents. As the contents of the synchronized folder are changed by any of the clients, the changes are propagated to the host system, which in turn delivers the changes to each of the clients registered as sharing that folder. In this way, each client participating in the share has a current version of the folder and its contents.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application Nos.61/233,773, filed on Aug. 13, 2009, and 61/233,787, filed on Aug. 13,2009, each of which is incorporated by reference herein in its entirety.

BACKGROUND

1. Field of the Invention

The present invention relates generally to sharing of data over anetwork. In particular, the present invention is directed tosynchronization of a folder and its contents shared between multipleclients.

2. Description of Related Art

People often use multiple computers on a regular basis. A typical usermay have a first computer at the office and a second computer at home,for example. Sharing documents between these multiple computersgenerally requires transferring the document from one to the other—forexample, a user may e-mail himself a copy of a document he is working onbefore leaving the office, so that he can resume working on it laterfrom home. If the user forgets to e-mail or bring the document home withhim, he must either go back to the office to retrieve it, or perhapsgive up until the morning. Some methods exist to allow remote access toa computer, for example using a virtual private network (VPN) to accessa corporate network from a remote location. However, if the user isaccessing the document remotely and loses his connection, he may losehis changes, be unable to continue, and may end up with a corrupteddocument.

In addition, a dramatic increase in telecommuting and decrease inbusiness travel has led to the need for people to collaborate on filesfrom locations remote from each other. This results in the passing ofdocuments back and forth, for example as e-mail attachments or throughinstant messaging file transfers. Not only is attaching files cumbersomefor many computer users, but where multiple iterations are involved, itis not difficult to end up with multiple versions of the same document,perhaps having the same or a similar file name, located in variousplaces on a user's hard drive. Worse still, two or more people may beediting local versions of a document on their own computers, resultingin multiple different current versions of a document than then have tobe painstakingly integrated to produce a usable version.

SUMMARY

The present invention enables synchronization of folders shared amongmultiple clients over a network. A first user of a first clientinstantiates a folder to be shared, and the folder and its contents aresynchronized with a host system. As the user makes changes to the folderand its contents on the first client, those changes are propagated tothe synchronized version on the host server. Other clients—which may be,for example, additional computer systems operated by the first user, orcomputer systems operated by multiple other users—who will be sharingthe synchronized folder register with the host system and obtain acurrent version of the synchronized folder and contents. As the contentsof the synchronized folder are changed by any of the clients, thechanges are propagated to the host system, which in turn delivers thechanges to each of the clients registered as sharing that folder. Inthis way, each client participating in the share has a current versionof the folder and its contents.

In various embodiments, historic versions of shared folders areretained, thus allowing users to examine and restore earlier versions asdesired. In addition, conflict resolution is provided, enabling users towork on shared folders even when not connected to the network; when aconnection is available, a conflict resolution check occurs to ensurethat changes made by the offline user do not overwrite changes made byother users during the period the offline user was offline. In variousembodiments, a web interface allows access to shared folders from anycomputer with network access.

Changes to files are propagated to and from the host system bytransferring only sets of blocks of a file that have undergone changes.This reduces network utilization and allows synchronization to proceedwithout interrupting the user's experience, while enabling the user towork on a file that is at all times local to his client.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of a host system and clients for maintainingsynchronized shared folders in accordance with an embodiment of thepresent invention.

FIG. 2 illustrates a user interface window for creating a sharedsynchronized folder in accordance with an embodiment of the presentinvention.

FIG. 3 illustrates a user interface window for creating a sharedsynchronized folder in accordance with an embodiment of the presentinvention.

FIG. 4 illustrates a user interface window for sharing a folder inaccordance with an embodiment of the present invention.

FIG. 5 is a block diagram of a client system for maintainingsynchronized shared folders in accordance with an embodiment of thepresent invention.

FIG. 6 is an interaction diagram illustrating synchronization of a newfolder in accordance with an embodiment of the present invention.

FIG. 7 illustrates a grouping and hashing process for files inaccordance with an embodiment of the present invention.

FIG. 8 is an interaction diagram illustrating synchronization of amodified folder in accordance with an embodiment of the presentinvention.

FIG. 9 is an interaction diagram illustrating conflict resolution duringsynchronization of a shared folder in accordance with an embodiment ofthe present invention.

FIG. 10 illustrates an interface for interacting with shared folders inaccordance with an embodiment of the present invention.

FIG. 11 illustrates a selection menu for sharing a folder in accordancewith an embodiment of the present invention.

DETAILED DESCRIPTION

System Architecture

FIG. 1 is a block diagram of a host system and clients for maintainingsynchronized shared folders in accordance with an embodiment of thepresent invention. System 100 includes a host system 110 and clients 108a, 108 b. Host system 110 further includes a metadata server 102; ablock server 104; and a notification server 106.

Metadata server 102 receives requests from clients to update theserver's copy of synchronized folders and provides clients with a listof metadata for files being synchronized. Block server 104 receives,stores, and serves blocks of data constituting synchronized files.Notification server 106 provides updates to clients when a synchronizedfolder has been updated on the server, and provides those notificationsto the clients. The operation of each of these components is describedfurther below.

Note that in various embodiments, sharing occurs at the folderlevel—that is, a folder and any files in that folder are shared amongclients, and kept synchronized by the clients and host system 110.Throughout this description therefore, we refer to both folders andfiles as being synchronized and shared.

Client 108 may be a personal computer such as a desktop or laptopcomputer, a mobile device, or any other computer system having a filesystem. Client 108 executes an operating system such as MicrosoftWindows, Mac OS, Unix, etc., and includes memory, storage, a networkinterface, and other conventional computer hardware not illustrated inFIG. 1 for clarity. Client 108 creates, modifies and deletes files onits storage system in a conventional manner via its operating system,with the modifications described here. In addition, and as describedfurther below, client 108 includes one or more synchronized folders. InFIG. 1, only two clients 108 a and 108 b are shown, but any number ofclients 108 may be sharing synchronized folders via host system 110.

Client 108 enables a user to create, modify and delete files on theclient's local file system, and for those actions to be synchronizedwith versions of the same files on host system 110 and on one or moreother client computers. In one embodiment, a user creates a folder anddesignates it as one that should be synchronized, and its contents arethen managed by client 108 to maintain that synchronization. In oneembodiment, a user can create a shared synchronized folder eitherthrough a user interface portion of client 108, or via a web server.FIG. 2 illustrates a user interface window 200 accessed via a webinterface. A user in the illustrated embodiment has an option to eithercreate a new folder or share an existing folder. In FIG. 2, the user haschosen to create a new folder called “Patent Applications.” Conversely,FIG. 3 illustrates a user interface window 300 that enables a user toselect from among existing folders to be shared. Once the user haschosen or created the folder to be shared, FIG. 4 illustrates a userinterface window 400 via which the user can invite those people withwhom he would like to share the folder. FIG. 10 and FIG. 11 provide aview of how a folder can be shared using software on client 108. FIG. 10and FIG. 11 are described further below with respect to namespaces.

FIG. 5 is a block diagram providing a more detailed view of client 108in accordance with an embodiment of the present invention. Client 108includes a client database 502, a sync engine 504, a hash engine 506, acommit module 508, a file transfer module 510, a list engine 512 and afile events engine 514. The operation of each of these modules isdescribed further below.

Synchronizing a New File

For purposes of illustration, and with reference to FIG. 6, we firstconsider the situation in which a user adds a new file to a synchronizedfolder. File events engine 514 monitors the state of files in thesynchronized folder to detect new files, modified files, and removedfiles. In various embodiments, the operating system sends 602 a messageto file events engine 514 indicating that a change has occurred to thesynchronized folder. In alternative embodiments, file events engine 514identifies changes by, for example, comparing attributes of files in thefolder on a periodic basis. Upon determining that a change has occurredto the synchronized folder, file events engine 514 informs 604synchronization engine 504 that a change has been detected, and thelocation (path) of the folder or file within the folder where the changehas occurred. In this case, the change to the folder is the addition ofa new file.

In various embodiments, and referring now to FIG. 7, synchronized files702 are grouped into fixed-sized blocks 704 a, 704 b, 704 c, 704 d. Theblock sizes may be, for example, 2 MB, 4 MB, etc., according to thepreference of the implementer. After sync engine 504 is informed by fileevents engine 514 that a change has occurred, sync engine 504 instructs606 (FIG. 6) hash engine 506 to create a hash of blocks 706 a, 706 b,706 c, 706 d. Hash engine 506 hashes each of the blocks in the fileusing any of a variety of known hashing algorithms, which in oneembodiment is the SHA256 function. A particular version of file 702 canbe identified as a concatenation of the hashes of its blocks, referredto as a block list. In the illustrated case, for example, the block listfor this version of file 702 is (abc,def,ghk,lmn). In addition, hashengine 506 also creates metadata 708 related to the changed file,including its path, modification time, size, whether it is a directory,and file attributes including, for example, permission settings. Hashengine 506 then returns 608 the metadata and block list to sync engine504.

Continuing with FIG. 6, sync engine 504 next provides 612 the metadatato commit module 508, and commit module 508 issues 614 a commit command,which includes the metadata 708, to metadata server 102. Since the fileis new and therefore being synchronized for the first time, metadataserver 102 has no record of the blocks in the block list associated withthe file 702. Metadata server 102 responds 616 to commit module 508 witha message, for example, “need blocks (abc,def,ghk,lmn),” indicating thathost system 110 requires the blocks identified in the block list. Syncengine 504 instructs 618 file transfer module 510 to transfer the neededblocks, and file transfer module 510 adds the blocks to a queue ofblocks to be transferred to block server 104 when a connection isopened. In one embodiment, each block and its associated hash value istransferred 620 to block server 104, and block server 104 uses thereceived hash as a check value by computing a hash of the receivedblocks. File transfer module 510 then informs sync engine 504 that theblocks have been successfully transferred, and block server 104 informsmetadata server 102 of the blocks that have been received.

Once the needed blocks have been transferred, sync engine 504 instructs622 commit module 508 to reissue the commit command to metadata server502. Metadata server 502 recognizes that block server 504 now has theblocks listed in the block list of the metadata 708, and accepts themetadata 708, keeping a record of it. Metadata server 102 returns 624 tocommit module 508 a unique ID (UUID) associated with the version of thefile 702 specified by the metadata 708.

Modifying a Synchronized File

FIG. 8 is an interaction diagram illustrating synchronization of amodified file in accordance with an embodiment of the present invention.File events engine 514 receives 802 a notification from the operatingsystem indicating that a change has occurred to the synchronized folder.In alternative embodiments, file events engine 514 identifies changesby, for example, comparing attributes of files in the folder on aperiodic basis. Upon determining that a change has occurred to thesynchronized folder, file events engine 514 informs 804 synchronizationengine 504 that a change has been detected, and the path of the folderor file within the folder where the change has occurred.

Sync engine 504 then instructs 806 hash engine 506 to create a hash ofblocks 706 a, 706 b, 706 c, 706 d. Hash engine 506 hashes each of theblocks in the changed file, resulting in a block list. In addition, hashengine 506 also creates other metadata 708 as described above. Hashengine 506 then returns 808 the hashed blocks and metadata including theblock list to sync engine 504.

Next, sync engine 504 provides 812 the metadata to commit module 508,and commit module 508 issues 814 a commit command to metadata server102. In one embodiment, the data provided by commit module 508 tometadata server 102 includes the modification time, the block list ofthe updated files as well as the block list of the previous version ofthe file, which is known as the parent block list. Assuming the newblocks have not yet been seen by block server 104, metadata server 102asks 816 client 108 to provide the missing blocks. Sync engine 504generates a patch for each new block that can be applied to its parentblock, and instructs 820 file transfer module 510 to transfer thosepatches. A patch can be created using multiple methods known to those ofskill in the art, for example including rsync. File transfer module 510adds the patches to a queue of blocks to be transferred to block server104 when a connection is opened. In one embodiment, each patch and itsassociated hash value is transferred 822 to block server 104, and blockserver 104 uses the received hash as a check value by computing a hashof the received blocks. File transfer module 510 then informs syncengine 504 that the patches have been successfully transferred, andblock server 104 informs metadata server 102 of the blocks that havebeen received.

Once the needed blocks have been transferred, sync engine 504 instructs824 commit module 508 to reissue the commit command to metadata server502. Metadata server 502 recognizes that block server 504 has the blockslisted in the block list of the metadata 708, and accepts the metadata708, keeping a record of it. Metadata server 102 returns 826 to commitmodule 508 a unique ID (UUID) associated with the version of the file702 specified by the metadata 708.

Synchronizing Across Multiple Clients

As described above, a client 108 with a synchronized folder informs hostsystem 110 when a file in a synchronized folder has been added, modifiedor deleted. Other clients may also have versions of the samesynchronized folder, which are updated via host system 110 as follows.

Referring again to FIG. 1, assume that a user of a first client 108 ahas created a folder and invited a user of client 108 b to share thefolder. The folder is immediately synchronized on host system 110 asdescribed above. In addition, both client 108 a and client 108 b arenoted by notification server 106 as being associated with that folder.In one embodiment, each of the clients registers with notificationserver 106; in alternative embodiments notification server is informedby metadata server 102 or by the originating client 108 a of the sharingrelationship.

When metadata server 102 receives and successfully executes a commitinstruction, notification server 106 in one embodiment informs allclients subscribed to that folder that the folder contents have changed.In an alternative embodiment, the client that initiated the change isnot informed of the change.

Upon receiving the notification, each client 108 sends a list request tometadata server 102, and in response receives file metadata for allfiles in subscribed folders. The client then examines the block list foreach file and identifies any listed blocks that the client does notalready have in its database 502. File transfer module 510 then asksblock server 104 for a patch from the parent block the client is inpossession of to the new block the client needs. Block server 104creates the patch and provides it to client 108 in response to therequest. Client 108 then applies the patch to the parent block to obtainthe updated block, which it then stores. Client 108 repeats the processfor each block that needs updating. At the conclusion of the process,the client's version of the file is synchronized with the updatedversion on host system 110.

In one embodiment, clients maintain an open network connection tonotification server 106. Where an open connection is not possible orfeasible, the connection is kept alive as much as practical, andreestablished as necessary.

Conflict Detection

FIG. 9 is an interaction diagram illustrating conflict detection inaccordance with an embodiment of the present invention. A conflict canarise if, for example, two clients 108 a and 108 b are sharing asynchronized folder, and one or both of the clients becomes disconnectedfrom the network linking them to host system 110. This may occur quiteeasily if a laptop is taken on the road, for example. Assume that client108 b remains connected to the network while client 108 a goes offline902. At that moment, each of the clients have identical versions offiles in synchronized folders, and identical associated metadata,including block lists for the files. Now, users of both clients makerevisions 904, 906 to their local versions of a file in a shared folder.Since client 108 b is connected to the network, her changes will beimmediately synchronized 908 with host system 110. The commitinstruction sent from her client to metadata server 102 includes theappropriate parent block list as well as the new block list for eachchanged file. Changes made by the user of client 108 a, however, willnot be synchronized while he is offline.

When client 108 a reestablishes a connection 910 to host system 110, hisclient's commit module 508 will attempt to commit the changes made whileoffline. However, because the version now current at host system 110 hasbeen updated in the interim, the parent block list sent by commit module508 will not match the parent block list on metadata server 102.Consequently, commit module 508 will reject the commit instruction, andinstead return an error 914 to client 108 a indicating that a conflicthas occurred and a more recent version of the file is available. In oneembodiment, a backup copy of the version as edited by the offline useris saved 916 on the client 108 a and/or host system 110, and the client108 a then synchronizes 918 its version of the file with the laterversion available from host system 110.

File Deletions

In one embodiment, any client 108 that is sharing a synchronized foldercan delete any file or subfolder in the folder, regardless of whocreated the folder. In an alternative embodiment, only the creator of afile or folder can delete it. In one embodiment, when a file is deleted,host system a14 maintains a copy of the file and its metadata for acertain amount of time, e.g., an hour, a day, a week, etc., and anyclient 108 may undelete the file, restoring to its previous location inthe shared folder.

When a file is deleted, in one embodiment client commit module 508issues a commit command to metadata server 102 that in one embodimentincludes a commit instruction and the parent block list, with no newblocks to be added. Metadata server 102 then changes the attributes ofthe file to indicate its deleted status, and notification server 106updates any subscribing clients. In some embodiments where deleted filesare not maintained once deleted, metadata server 102 instructs blockserver 104 to delete the blocks in the deleted file's block list. Torestore a file, client 108 issues a list command with a flag indicatinga request for all available deleted files to metadata server 102.Metadata server 102 responds with a list of deleted files that are stillavailable to be restored. Commit module 508 then issues a restorecommand, and metadata server 102 changes the attribute of the deletefile to indicate it is no longer deleted. Notification server 106 thenissues an update to clients sharing the folder to which the restoredfile belongs.

In one embodiment, system 100 enables multiple versions of a singlesynchronized file to be reviewed. In a manner similar to that describedabove with respect to file deletions, when a new version of a file issynchronized with metadata server 102, metadata server 102 maintains themetadata and block list for the previous version of the file. The blocksremain stored on block server 104, and upon instruction from a user of aclient 108, metadata server 102 instructs block server 104 to provide afile consisting of the blocks in the previous version. This enables auser to preview an earlier version, and if desired, to restore it to thecurrent version, in which case metadata server 102 simply updates thecurrent version to reflect the block list of the version being restored.

Mapping Namespaces

In one embodiment, host system 110 performs namespace mapping functions,allowing users of system 100 to interact seamlessly with shared foldersthrough their operating system's standard user interface. Assume a firstuser has a folder that is synchronized with host system 110. Referringto FIG. 10, the “My Dropbox” folder 1002 is such a folder. In oneembodiment, the synchronized folder 1002 exists in a first name space,which for purposes of example we will refer to as “1:”. In the exampleof FIG. 10, the folders Music, Patent Applications, Photos, and Public,and the document Getting Started.rtf are each stored also in namespace1:. Note also that the “My Dropbox” folder 1002 in the illustratedembodiment is displayed next to other conventional folders such as “MyMeetings”, “My Received Files,” and others.

Assume now that the user indicates that he wishes to share the “PatentApplications” folder. In one embodiment, a user can indicate thisthrough a user interface command, such as by right-clicking on thefolder name and selecting a “Share This Folder . . . ” option 1102, asillustrated in FIG. 11. Alternatively, the user can use a web interfaceto communicate the share instructions to host system 110. In eitherevent, the user also specifies the account identifier of the user(s)with whom the folder is to be shared.

Metadata server 102 receives the share instruction and moves thesubfolder “Patent Applications” from the path “1:/Patent Applications”to a new namespace, which we will call “2:”. Metadata server 102 thencreates a mapping from the namespace “1:/Patent Applications” to thenamespace “2:”, and instructs the client to do the same. Note that fromthe point of view of the user, nothing appears to have changed in theuser interface.

Assume now that the invited user has an existing namespace, “3:”.Assuming the user accepts the invitation to share the folder, metadataserver 102 creates a link in the 3: namespace, such that “3:/PatentApplications” points to namespace 2:. Metadata server 102 also adds theinvited user's identifier to the list of users sharing the folder, andnotification server 106 begins providing change notifications to theinvited user's client. The invited user's client then obtains the latestversion of the synchronized file according to the methods describedabove.

At some point, either the client who initiated the sharing of thesynchronized folder, or any of the clients who subscribed to the sharedfolder may decide to end the sharing arrangement. At that time, metadataserver 102 removes the namespace mappings initiated when the share withthat client was created. In the example above, if the invited userdecided to stop sharing the folder, then the link from “3:/PatentApplications” to namespace 2: would be removed. If the original userwere to disable sharing for the folder, then any invited users would beunlinked from the folder as just described. In one embodiment, thefolder remains in namespace 2: and the mapping from namespace “1:/PatentApplications” to namespace 2: remains intact. In an alternativeembodiment, the folder is returned to its original location in namespace1:.

As noted, client 108 may be executed on a computer system with variousoperating systems, including Microsoft Windows, Mac OS, Linux, andmobile operating systems such as Apple iOS. Where folders are shared,the sharing need not be between clients running on the same operatingsystem. For example, client 108 a may be hosted by a Mac OS operatingsystem while client 108 b is on a system running Microsoft Windows.

A single user may have multiple computers, each of which may or may notbe running the same operating system. Using system 100, the user canmaintain documents and files in a synchronized folder, and have thecontents of that folder available to him regardless of which of hiscomputers and at which location he happens to be at the moment he needsthem, without having to worry about which version is available on whichcomputer.

The present invention has been described in particular detail withrespect to a limited number of embodiments. Those of skill in the artwill appreciate that the invention may additionally be practiced inother embodiments.

Within this written description, the particular naming of thecomponents, capitalization of terms, the attributes, data structures, orany other programming or structural aspect is not mandatory orsignificant, and the mechanisms that implement the invention or itsfeatures may have different names, formats, or protocols. Further, thesystem may be implemented via a combination of hardware and software, asdescribed, or entirely in hardware elements. Also, the particulardivision of functionality between the various system componentsdescribed herein is merely exemplary, and not mandatory; functionsperformed by a single system component may instead be performed bymultiple components, and functions performed by multiple components mayinstead be performed by a single component.

Some portions of the above description present the feature of thepresent invention in terms of algorithms and symbolic representations ofoperations on information. These algorithmic descriptions andrepresentations are the means used by those skilled in the art to mosteffectively convey the substance of their work to others skilled in theart. These operations, while described functionally or logically, areunderstood to be implemented by computer programs. Furthermore, it hasalso proven convenient at times, to refer to these arrangements ofoperations as modules or code devices, without loss of generality.

It should be borne in mind, however, that all of these and similar termsare to be associated with the appropriate physical quantities and aremerely convenient labels applied to these quantities. Unlessspecifically stated otherwise as apparent from the present discussion,it is appreciated that throughout the description, discussions utilizingterms such as “selecting” or “computing” or “determining” or the like,refer to the action and processes of a computer system, or similarelectronic computing device, that manipulates and transforms datarepresented as physical (electronic) quantities within the computersystem memories or registers or other such information storage,transmission or display devices.

Certain aspects of the present invention include process steps andinstructions described herein in the form of an algorithm. It should benoted that the process steps and instructions of the present inventioncould be embodied in software, firmware or hardware, and when embodiedin software, could be downloaded to reside on and be operated fromdifferent platforms used by real time network operating systems.

The present invention also relates to an apparatus for performing theoperations herein. This apparatus may be specially constructed for therequired purposes, or it may comprise a general-purpose computerselectively activated or reconfigured by a computer program stored inthe computer. Such a computer program may be stored on a non-transitorycomputer readable storage medium, such as, but is not limited to, anytype of disk including floppy disks, optical disks, DVDs, CD-ROMs,magnetic-optical disks, read-only memories (ROMs), random accessmemories (RAMs), EPROMs, EEPROMs, magnetic or optical cards, applicationspecific integrated circuits (ASICs), or any type of media suitable forstoring electronic instructions, and each coupled to a computer systembus. Furthermore, the computers referred to in the specification mayinclude a single processor or may be architectures employing multipleprocessor designs for increased computing capability.

The algorithms and displays presented herein are not inherently relatedto any particular computer or other apparatus. Various general-purposesystems may also be used with programs in accordance with the teachingsherein, or it may prove convenient to construct more specializedapparatus to perform the required method steps. The required structurefor a variety of these systems will appear from the description above.In addition, the present invention is not described with reference toany particular programming language. It is appreciated that a variety ofprogramming languages may be used to implement the teachings of thepresent invention as described herein, and any references to specificlanguages are provided for disclosure of enablement and best mode of thepresent invention.

Finally, it should be noted that the language used in the specificationhas been principally selected for readability and instructionalpurposes, and may not have been selected to delineate or circumscribethe inventive subject matter. Accordingly, the disclosure of the presentinvention is intended to be illustrative, but not limiting, of the scopeof the invention.

We claim:
 1. A method for synchronizing a shared folder over a network, the method comprising: receiving a first file and an associated first block list at a host system from a first client system; associating the received file with a synchronized folder on the host system, the synchronized folder having an associated first namespace and the folder including a plurality of files, each of the plurality of files having an associated block list; receiving a request from the first client system to share the synchronized folder with a second client system; associating the synchronized folder with a second namespace; associating the synchronized folder with the second client system; receiving a request from the second client system for contents of the synchronized folder; providing to the second client system a link from a third namespace to the second namespace, and an indication of each of the plurality of files and its associated block list in the synchronized folder; receiving at the host system a request from the second client system for the first file, the request including blocks identified in the provided first block list; providing the first file including the requested blocks to the second client system; receiving at the host system from the first client system a modification to the first file; updating the first file and its associated first block list according to the received modification; providing an indication to the second client system that the contents of the folder have changed, the indication including the first block list and the updated block list associated with the first file; receiving a request from the second client system for the modification to the first file; and sending, by the host system, a difference between the blocks in the updated block list and the first block list.
 2. The method of claim 1 wherein each block identified in the first block list is a hash of a portion of the first file.
 3. The method of claim 1 further comprising: providing an indication to a third client system that the contents of the folder have changed, the indication including the first and the updated first block list associated with the first file; receiving a request from the third client system for the modification to the first file; and sending, by the host system to the third client system the difference between the blocks in the updated first block list and the first block list.
 4. The method of claim 1 further comprising: receiving, by a notification server at the host system, a request from a plurality of additional client systems to be notified of modifications to the synchronized folder; informing, by the host system, the plurality of additional client systems that the first file has been modified; receiving, by the host system from at least one of the plurality of additional clients, a request for one of the blocks in the updated first block list, the request also identifying at least one of the blocks in the first block list; determining, by a block server, a difference between the identified first block and the requested updated first block; and sending, by the block server to the additional client, the determined difference between the identified first block and the requested updated first block.
 5. A computer program product for synchronizing a folder across a computer network, the computer program product stored on a non-transitory computer readable medium and including instructions that when loaded into memory cause a computer processor to carry out the steps of: receiving a first file and an associated first block list at a host system from a first client system; associating the received file with a synchronized folder on the host system, the synchronized folder having an associated first namespace and the folder including a plurality of files, each of the plurality of files having an associated block list; receiving a request from the first client system to share the synchronized folder with a second client system; associating the synchronized folder with a second namespace; associating the synchronized folder with the second client system; receiving a request from the second client system for contents of the synchronized folder; providing to the second client system a link from a third namespace to the second namespace, and an indication of each of the plurality of files and its associated block list in the synchronized folder; receiving at the host system a request from the second client system for the first file, the request including blocks identified in the provided first block list; providing the first file including the requested blocks to the second client system; receiving at the host system from the first client system a modification to the first file; updating the first file and its associated first block list according to the received modification; providing an indication to the second client system that the contents of the folder have changed, the indication including the first block list and the updated block list associated with the first file; receiving a request from the second client system for the modification to the first file; and sending, by the host system, a difference between the blocks in the updated block list and the first block list.
 6. The computer program product of claim 5 wherein the instructions further cause the processor to carry out the steps of: providing an indication to a third client system that the contents of the folder have changed, the indication including the first and the updated first block list associated with the first file; receiving a request from the third client system for the modification to the first file; and sending, by the host system to the third client system the difference between the blocks in the updated first block list and the first block list.
 7. The computer program product of claim 5 wherein the instructions further cause the processor to carry out the steps of: receiving, by a notification server at the host system, a request from a plurality of additional client systems to be notified of modifications to the synchronized folder; informing, by the host system, the plurality of additional client systems that the first file has been modified; receiving, by the host system from at least one of the plurality of additional clients, a request for one of the blocks in the updated first block list, the request also identifying at least one of the blocks in the first block list; determining, by a block server, a difference between the identified first block and the requested updated first block; and sending, by the block server to the additional client, the determined difference between the identified first block and the requested updated first block.
 8. The computer program product of claim 5 wherein each block identified in the first block list is a hash of a portion of the first file. 